TD-SCDMA DesignGuide May 2007

TD-SCDMA DesignGuide May 2007

Notice The information contained in this document is subject to change without notice. Agilent Technologies makes no warranty of any kind with regard to this material, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. Agilent Technologies shall not be liable for errors contained herein or for incidental or consequential damages in connection with the furnishing, performance, or use of this material. Warranty A copy of the specific warranty terms that apply to this software product is available upon request from your Agilent Technologies representative. Restricted Rights Legend Use, duplication or disclosure by the U. S. Government is subject to restrictions as set forth in subparagraph (c) (1) (ii) of the Rights in Technical Data and Computer Software clause at DFARS 252.227-7013 for DoD agencies, and subparagraphs (c) (1) and (c) (2) of the Commercial Computer Software Restricted Rights clause at FAR 52.227-19 for other agencies. Agilent Technologies, Inc. 1983-2007. 395 Page Mill Road, Palo Alto, CA 94304 U.S.A. Acknowledgments Mentor Graphics is a trademark of Mentor Graphics Corporation in the U.S. and other countries. Microsoft, Windows, MS Windows, Windows NT, and MS-DOS are U.S. registered trademarks of Microsoft Corporation. Pentium is a U.S. registered trademark of Intel Corporation. PostScript and Acrobat are trademarks of Adobe Systems Incorporated. UNIX is a registered trademark of the Open Group. Java is a U.S. trademark of Sun Microsystems, Inc. SystemC is a registered trademark of Open SystemC Initiative, Inc. in the United States and other countries and is used with permission. MATLAB is a U.S. registered trademark of The Math Works, Inc. ii

Contents 1 TD-SCDMA Standard Introduction... 1-1 Physical Layer... 1-1 DesignGuide Examples Overview... 1-3 2 TD-SCDMA BER Performance Designs Introduction... 2-1 12.2k Uplink Channel with AWGN... 2-2 12.2k Uplink Fading Channel with Joint Detection Receiver... 2-4 12.2k Downlink Fading Channel... 2-7 3 TD-SCDMA Instrument Link Designs Introduction... 3-1 Base Station Signal Generated Using ADS-ESGc Link Measured by VSA89600... 3-2 User Equipment Signal Generated Using ADS-ESGc Link Measured by VSA89600 3-5 4 TD-SCDMA Power Amplifier Designs Introduction... 4-1 Complementary Cumulative Distribution Function Measurements... 4-2 Power vs. Time Measurement... 4-4 CCDF and Spectrum Measurements of Multi-carrier Signal... 4-6 5 TD-SCDMA Receiver Designs Introduction... 5-1 Base Station Reference Sensitivity Level... 5-2 User Equipment Adjacent Channel Selectivity... 5-4 6 TD-SCDMA Signal Source Designs Introduction... 6-1 Uplink Signal Characteristics... 6-2 Adjacent Channel Power Leakage Ratio... 6-6 Rate Match Calculator... 6-8 7 TD-SCDMA Transmitter Designs Introduction... 7-1 Base Station Error Vector Magnitude... 7-2 User Equipment Code Domain Power... 7-5 Index iii

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Chapter 1: TD-SCDMA Standard Introduction TD-SCDMA is a Chinese contribution to the international family of Mobile Radio Systems for 3G services of UMTS and IMT 2000. It is now one option of UTRA-TDD, called 1.28Mcps TDD or low chip rate (LCR) TDD. It is an advanced CDMA/TDMA/TDD system with an adaptive synchronous operation. TD-SCDMA system simulation models based on the 3GPP TDD LCR standard demonstrate signal generation capabilities; basic measurements are considered. TD-SCDMA aligns with the same version of the specification used by the Agilent ESG-C, PSA II and VSA. Physical Layer The frame structure, illustrated in Figure 1-1, recognizes new smart antenna and uplink synchronization technologies. Radio frame (10 msec) frame #i frame #i+1 sub-frame (5 msec) sub-frame #1 sub-frame #2 time-slot #0 time-slot #1 time-slot #2 time-slot #6 Figure 1-1. Physical Channel Signal Format Uplink and downlink time slots in each frame are separated by a switching point. There are two switching points in each sub-frame: TS0 is always allocated as downlink; TS1 is always allocated as uplink. There are three special time slots: Introduction 1-1

TD-SCDMA Standard DwPTS: downlink pilot time slot, 96 chip duration UpPTS: uplink pilot time slot, 160 chip duration GP: main guard period for TDD operation, 96 chip duration The system can operate on symmetric and asymmetric modes by properly configuring the number of downlink and uplink time slots. The burst structure is illustrated in Figure 1-2. First part of TFCI code word SS symbols TPC symbols Third part of TFCI code word SS symbols TPC symbols Data Symbols Midamble Data Symbols G P Data Symbols Midamble Data Symbols G P Second part of TFCI code word Fourth part of TFCI code word Time slot x (864 chips) Time slot x (864 chips) Sub-frame 5 msec Sub-frame 5 msec Radio Frame 10 msec Figure 1-2. Burst Structure The transmitter structure of a physical channel is illustrated in Figure 1-3. 1-2 Introduction

Figure 1-3. Physical Channel Transmitter Structure There are two kinds of receiver algorithm for TD-SCDMA: Rake and Joint Detection. Physical channels have a 3-layer structure. Time slot: 675 usec slot consisting of a number of Symbols. Time slots are used in a TDMA component to separate different user signals in time and code domain. Radio frame: 5 msec frame consisting of 7 time slots System frame numbering DesignGuide Examples Overview Example designs are provided in the /examples/tdscdma directory. Projects and their corresponding design examples are: The TDSCDMA_BER project demonstrates BER and BLER performance. BER and BLER performance of a 12.2k uplink channel with AWGN: TDSCDMA_12_2_UL_AWGN.dsn BER and BLER performance of a 12.2k uplink reference fading channel with joint detection receiver: TDSCDMA_12_2_UL_Fading_JD.dsn DesignGuide Examples Overview 1-3

TD-SCDMA Standard BER and BLER performance of a 12.2k downlink fading channel with joint detection receiver: TDSCDMA_12_2_DL_Fading_JD.dsn The TD-SCDMA_LinkTest project demonstrates the characteristics of ADS and instrument links. Base station signal generated using ADS-ESGc link measured by VSA89600: TDSCDMA_DL_Link.dsn. User equipment signal generated using ADS-ESGc link measured by VSA89600: TDSCDMA_UL_Link.dsn. The TDSCDMA_PA_Test project includes these design examples. Characterization of peak average power ratio versus probability: TDSCDMA_DL_CCDF.dsn. Instant and average power versus time measurements: TDSCDMA_UL_Power_vs_Time.dsn. CCDF and spectrum of multi-carrier signal measurements: TDSCDMA_MC_Test.dsn. The TDSCDMA_Rx project demonstrates user equipment and base station characteristics. BTS reference sensitivity level: TDSCDMA_UL_Sensitivity.dsn. UE adjacent channel selectivity: TDSCDMA_DL_AdjacentChannel.dsn. The TDSCDMA_SignalSource project demonstrates the special transient characteristics of TD-SCDMA signals from time and frequency domains. Uplink signal characteristics: TDSCDMA_UL_Spectrum.dsn. Downlink signal characteristics: TDSCDMA_DL_ACLR.dsn. The TDSCDMA_Tx project demonstrates user equipment and base station characteristics. Base station error vector magnitude: TDSCDMA_DL_EVM.dsn. User equipment code domain power: TDSCDMA_UL_CDP.dsn. 1-4 DesignGuide Examples Overview

Chapter 2: TD-SCDMA BER Performance Designs Introduction The TDSCDMA_BER project demonstrates BER and BLER performance. Three example designs are included in this project: BER and BLER performance of a 12.2k uplink channel with AWGN: TDSCDMA_12_2_UL_AWGN.dsn BER and BLER performance of a 12.2k uplink reference fading channel with joint detection receiver: TDSCDMA_12_2_UL_Fading_JD.dsn BER and BLER performance of a 12.2k downlink fading channel with joint detection receiver: TDSCDMA_12_2_DL_Fading_JD.dsn Introduction 2-1

TD-SCDMA BER Performance Designs 12.2k Uplink Channel with AWGN TDSCDMA_12_2_UL_AWGN.dsn Description BER and BLER performance of a 12.2k uplink channel with AWGN is demonstrated in this design. The top-level schematic for this design is shown in Figure 2-1. TDSCDMA_RefCh_RF is used to generate an uplink RF reference measurement channel. One physical channel is used to carry one DCH and one DCCH. The spreading factor is 8. A convolution encoder is used. The code rate is 1/3 and the constraint length is 7. A rate match component is placed after the encoder with a 1/3 puncture rate. A Rake receiver is applied. Figure 2-1. TDSCDMA_12_2_UL_AWGN.dsn Schematic 2-2 12.2k Uplink Channel with AWGN

Simulation Results Simulation results are displayed in Figure 2-2. Benchmark Figure 2-2. Simulation Results Hardware Platform: Pentium 4 1.8GHz, 512 MB memory Software Platform: Windows XP, ADS 2003A Simulation Time: 20 hours References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. 12.2k Uplink Channel with AWGN 2-3

TD-SCDMA BER Performance Designs 12.2k Uplink Fading Channel with Joint Detection Receiver TDSCDMA_12_2_UL_Fading_JD.dsn Description BER and BLER performance of a 12.2k uplink reference fading channel with joint detection receiver is demonstrated in this design. The top-level schematic for this design is shown in Figure 2-3. Figure 2-3. TDSCDMA_12_2_UL_Fading_JD.dsn Schematic TDSCDMA_RefCh_RF is used to generate an uplink reference measurement channel. One DPCH is used to carry one DCH and one DCCH. The spreading factor is 8. A convolution encoder is used. The code rate is 1/3 and the constraint length is 7. A rate match component is placed after the encoder with a 1/3 puncture rate. Table 2-1 lists propagation conditions (defined in [1] ) for multi-path fading environment performance measurements (Case 3 is applied in this design). All taps have classical Doppler spectrum. 2-4 12.2k Uplink Fading Channel with Joint Detection Receiver

Table 2-1. Propagation Conditions for Multi-Path Fading Environments Simulation Results Case 1, 3 km/hr Case 2, 3 km/hr Case 3, 120 km/hr Relative Delay (nsec) Average Power (db) Relative Delay (nsec) Simulation results are displayed in Figure 2-4. Average Power (db) Relative Delay (nsec) 0 0 0 0 0 0 2928-10 2928 0 781-3 1200 0 1563-6 2344-9 Average Power (db) Figure 2-4. Simulation Results Benchmark Hardware Platform: Pentium 4 2.3GHz, 512 MB memory Software Platform: Windows 2000, ADS 2003C 12.2k Uplink Fading Channel with Joint Detection Receiver 2-5

TD-SCDMA BER Performance Designs Simulation Time: 60 hours References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. 2-6 12.2k Uplink Fading Channel with Joint Detection Receiver

12.2k Downlink Fading Channel TDSCDMA_12_2_DL_Fading_JD.dsn Description BER and BLER performance of a 12.2k downlink fading channel with joint detection receiver is demonstrated in this design. The top-level schematic for this design is shown in Figure 2-5. Figure 2-5. TDSCDMA_12_2_DL_Fading_JD.dsn Schematic TDSCDMA_RefCh_RF is used to generate a downlink reference measurement channel. Two DPCHs carry one DCH and one DCCH. The spreading factor is 16. A convolution encoder is used. The code rate is 1/3 and the constrain length is 7. A rate matching component is placed after the encoder with a 1/3 puncture rate. A joint detection receiver is applied. Table 2-2 lists propagation conditions (defined in [1] ) for multi-path fading environment performance measurements (Case 3 is applied in this design). 12.2k Downlink Fading Channel 2-7

TD-SCDMA BER Performance Designs Table 2-2. Propagation Conditions for Multi-Path Fading Environments Simulation Results Case 1, 3 km/hr Case 2, 3 km/hr Case 3, 120 km/hr Relative Delay (nsec) Average Power (db) Relative Delay (nsec) Simulation results are displayed in Figure 2-6. Average Power (db) Relative Delay (nsec) 0 0 0 0 0 0 2928-10 2928 0 781-3 1200 0 1563-6 2344-9 Average Power (db) Figure 2-6. Simulation Results Benchmark Hardware Platform: Pentium 4 2.3GHz, 512 MB memory Software Platform: Windows 2000, ADS 2003C 2-8 12.2k Downlink Fading Channel

Simulation Time: 35 hours References [1] 3GPP Technical Specification TS 34.122 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. 12.2k Downlink Fading Channel 2-9

TD-SCDMA BER Performance Designs 2-10 12.2k Downlink Fading Channel

Chapter 3: TD-SCDMA Instrument Link Designs Introduction The TD-SCDMA_LinkTest project demonstrates the characteristics of ADS and instrument links. Design examples in this project are described in the following sections: Base station signal generated using ADS-ESGc link measured by VSA89600: TDSCDMA_DL_Link.dsn. User equipment signal generated using ADS-ESGc link measured by VSA89600: TDSCDMA_UL_Link.dsn. Introduction 3-1

TD-SCDMA Instrument Link Designs Base Station Signal Generated Using ADS-ESGc Link Measured by VSA89600 TDSCDMA_DL_Link.dsn Description This design demonstrates ADS and instrument links. The BTS signal is generated using ADS-ESGc link, then measured by VSA89600. The top-level schematic for this design is shown in Figure 3-1. TDSCDMA_DL_RF is used to generate downlink RF signal. VSA_89600_1_Sink is used to start VSA89600 software to measure the RF signal. ESG_E4438C_Sink is used to send I, Q data to ESG. Figure 3-1. TDSCDMA_DL_Link.dsn Schematic 3-2 Base Station Signal Generated Using ADS-ESGc Link Measured by VSA89600

Simulation Results Simulation results are displayed in VSA89600 window and shown in Figure 3-2. Figure 3-2. TDSCDMA_DL_Link.dsn Simulation Results Base Station Signal Generated Using ADS-ESGc Link Measured by VSA89600 3-3

TD-SCDMA Instrument Link Designs Benchmark Hardware Platform: Pentium III 800 MHz, 512 MB memory Software Platform: Windows 2000, ADS 2002C, VSA89600 4.00x2_BETA Simulation Time: N/A References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Confromance(TDD) (Release 4) June, 2002. 3-4 Base Station Signal Generated Using ADS-ESGc Link Measured by VSA89600

User Equipment Signal Generated Using ADS-ESGc Link Measured by VSA89600 TDSCDMA_UL_Link.dsn Description This design demonstrates ADS and instrument links. The user equipment signal is generated using ADS-ESGc link, then measured by VSA89600. The top-level schematic for this design is shown in Figure 3-3. TDSCDMA_DL_RF is used to generate uplink RF signal. VSA_89600_1_Sink is used to start VSA89600 software to measure the RF signal. ESG_E4438C_Sink is used to send I, Q data to ESG. Figure 3-3. TDSCDMA_UL_Link.dsn Schematic User Equipment Signal Generated Using ADS-ESGc Link Measured by VSA89600 3-5

TD-SCDMA Instrument Link Designs Simulation Results Simulation results are displayed in VSA89600 window and shown in Figure 3-4. Benchmark Figure 3-4. TDSCDMA_UL_Link.dsn Simulation Results Hardware Platform: Pentium III 800 MHz, 512 MB memory Software Platform: Windows 2000, ADS 2002C, VSA89600 4.00x2_BETA Simulation Time: N/A References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Confromance (TDD) (Release 4) June, 2002. 3-6 User Equipment Signal Generated Using ADS-ESGc Link Measured by VSA89600

Chapter 4: TD-SCDMA Power Amplifier Designs Introduction The TDSCDMA_PA_Test project includes these design examples. Characterization of peak average power ratio versus probability: TDSCDMA_DL_CCDF.dsn. Instant and average power versus time measurements: TDSCDMA_UL_Power_vs_Time.dsn. CCDF and spectrum of multi-carrier signal measurements: TDSCDMA_MC_Test.dsn. Introduction 4-1

TD-SCDMA Power Amplifier Designs Complementary Cumulative Distribution Function Measurements TDSCDMA_PA_Test_prj Design Name TDSCDMA_DL_CCDF.dsn Features Configurable signal source subnetwork model. DUT_Gain, FCarrier, Power, SamplesPerSymbol and SlotIndex parameter values can be set by the user. Description Complementary cumulative distribution function (CCDF) fully characterizes the power statistics of a signal. It provides peak-average ratio versus probability. The top-level schematic for this design is shown in Figure 4-1. Simulation Results Figure 4-1. TDSCDMA_DL_CCDF.dsn Schematic Simulation results are displayed in TDSCDMA_DL_CCDF.dds. Page main, Figure 4-2, contains the most important final results and indicates if the measurement results met the requirement of technical specification. In this 4-2 Complementary Cumulative Distribution Function Measurements

measurement, the test results would always be passed since there is no requirement of CCDF in TD-SCDMA technical specification. Page figures, Figure 4-3, shows the CCDF curve. Page equations contains all variable definitions and calculations. Figure 4-2. Page Main of Simulation Results Benchmark Figure 4-3. Page Figures of Simulation Results Hardware Platform: Pentium II 400 MHz, 512 MB memory Software Platform: Windows NT 4.0 Workstation, ADS 2002 Simulation Time: approximately 3 minutes References [1] 3GPP TS 25.221, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Physical channels and mapping of transport channels onto physical channels onto physical channels (TDD) (Release 4), version 4.3.0, Dec., 2001 Complementary Cumulative Distribution Function Measurements 4-3

TD-SCDMA Power Amplifier Designs Power vs. Time Measurement TDSCDMA_UL_Power_vs_Time.dsn Features Power vs. time measurement 12.2kbps uplink reference measurement channel Roll-off Description α= 0.22 root raised-cosine filter This example measures power vs. time for TD-SCDMA uplink. Power vs. time is calculated by averaging the power of chips at the same position in all measured subframes. The schematic for this design is shown in Figure 4-4. TDSCDMA_UL_RF generates the 12.2k measurement channel. TDSCDMA_PwrMeasure implements the power measurement. Figure 4-4. TDSCDMA_Power_vs_Time Schematic 4-4 Power vs. Time Measurement

Simulation Results Simulation results are displayed in Figure 4-5. The Equations page shows the equations that are used for calculating the mask. Benchmark Figure 4-5. Power vs. time for TD-SCDMA Uplink Hardware Platform: Pentium II 400 MHz, 512 MB memory Software Platform: Windows NT Workstation 4.0, ADS 2001 Simulation Time: approximately 2 minutes References [1] 3GPP TS 25.102, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; UTRA(UE) TDD; Radio transmission and Reception (Release 4), version 4.3.0, Dec., 2001 Power vs. Time Measurement 4-5

TD-SCDMA Power Amplifier Designs CCDF and Spectrum Measurements of Multi-carrier Signal TDSCDMA_PA_Test_prj Design Name TDSCDMA_MC_Test.dsn Features Multi-carrier signal source with 16 code channels on each carrier. FCarrier, FiletrLength, SamplesPerSymbol, DUT_Gain, NumSlotsMeasured and SystemDelay parameter values can be set by the user. Description The top-level schematic for this design is shown in Figure 4-6. Figure 4-6. TDSCDMA_MC_Test Schematic The sub_tdscdma_channel16_mc provides multi-carrier signal on (1900-1.6)MHz, 1900MHz and (1900+1.6)MHz. The CCDFMeasurementMC and SpectrumAnalyzer is used to measure the CCDF and spectrum of the multi-carrier signal and the CCDFMeasurementSC is used to measure the CCDF of the single-carrier signal on 1900MHz. 4-6 CCDF and Spectrum Measurements of Multi-carrier Signal

The sub_tdscdma_channel16_mc schematic is shown in Figure 4-7. Figure 4-7. sub_tdscdma_channel16_mc Schematic X1, X2 and X3 are sub_tdscdma_channel16 subnetworks which provide baseband signal of a subframe including 16 code channels in time slot 6 and null in other time slots. X1 is modulated to 1900 MHz, X2 to (1900-1.6) MHz and X3 to (1900+1.6) MHz. Simulation Results Simulation results displayed in TDSCDMA_MC_Test.dds are shown in Figure 4-8. CCDF and Spectrum Measurements of Multi-carrier Signal 4-7

TD-SCDMA Power Amplifier Designs Benchmark Figure 4-8. Simulation Results Hardware Platform: Pentium III 1 GHz, 512 MB memory Software Platform: Windows 2000, ADS 2002 Simulation Time: approximately 5 minutes References [1] 3GPP TS 25.221, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Physical channels and mapping of transport channels onto physical channels onto physical channels (TDD) (Release 4), version 4.3.0, Dec., 2001 4-8 CCDF and Spectrum Measurements of Multi-carrier Signal

Chapter 5: TD-SCDMA Receiver Designs Introduction The TD-SCDMA receiver project demonstrates user equipment and base station characteristics. Design examples in this project are described in the following sections: BTS reference sensitivity level: TDSCDMA_UL_Sensitivity.dsn. UE adjacent channel selectivity: TDSCDMA_DL_AdjacentChannel.dsn. Introduction 5-1

TD-SCDMA Receiver Designs Base Station Reference Sensitivity Level TDSCDMA_UL_Sensitivity.dsn Description This design measures the base station reference sensitivity level. The reference sensitivity level is the minimum mean power received at the antenna connector at which BER cannot exceed the value given in Table 5-1. Reference Measurement Channel Data Rate Table 5-1. BS Reference Sensitivity Level BS Reference Sensitivity Level The top-level schematic for this design is shown in Figure 5-1. TDSCDMA_RefCh_RF is used to generate 12.2 kbps uplink RF signal. TDSCDMA_12_2_UL_RakeReceiver is used to receive the uplink RF signal with data rate 12.2 kbps. TDSCDMA_BER is used to measure the BER TDSCDMA_RF_PwrMeasure is used to measure the mean power at the input port of the receiver. BER 12.2 kbps -110 dbm BER cannot exceed 0.001 Figure 5-1. TDSCDMA_UL_Sensitivity.dsn Schematic 5-2 Base Station Reference Sensitivity Level

Simulation Results Simulation results are displayed in the data display window and shown in Figure 5-2. Benchmark Figure 5-2. TDSCDMA_UL_Sensitivity.dsn Simulation Results Hardware Platform: Pentium III 400 MHz, 512 MB memory Software Platform: Windows NT, ADS 2002 Simulation Time: approximately 6 hours References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. Base Station Reference Sensitivity Level 5-3

TD-SCDMA Receiver Designs User Equipment Adjacent Channel Selectivity TDSCDMA_DL_AdjacentChannel.dsn Description This design measures the adjacent channel selectivity. Adjacent channel selectivity is a measure of the receiver s ability to receive a wanted signal at its assigned channel frequency in the presence of an adjacent channel signal. For the user equipment power class 2 and 3, the BER cannot exceed 0.001for parameters specified in Table 5-2. This test condition is equivalent to an adjacent channel selectivity value of 33 db. Table 5-2. Test Parameters for Adjacent Channel Selectivity Parameter Unit Level ΣDPCH Ec --------------------------------- I or db 0 I or dbm/1.28 MHz -91 I osc dbm/1.28 MHz -54 F uw offset MHz +1.6 or -1.6 The top-level schematic for this design is shown in Figure 5-3. The upper TDSCDMA_RefCh_RF is used to generate wanted 12.2 kbps downlink RF signal; the lower TDSCDMA_RefCh_RF is the adjacent channel signal. TDSCDMA_12_2_DL_RakeReceiver is used to receive the wanted downlink RF signal with a 12.2 kbps data rate in the presence of adjacent channel signal. TDSCDMA_BER is used to measure the BER. TDSCDMA_RF_PwrMeasure is used to measure the mean power at the input port of the receiver. 5-4 User Equipment Adjacent Channel Selectivity

Simulation Results Figure 5-3. TDSCDMA_DL_AdjacentChannel.dsn Schematic Simulation results are shown in Figure 5-4. Figure 5-4. Adjacent Channel Selectivity Measurement Results User Equipment Adjacent Channel Selectivity 5-5

TD-SCDMA Receiver Designs Benchmark Hardware Platform: Pentium III 450MHz, 512MB memory Software Platform: Windows 2000, ADS 2002 Simulation Time: approximately 9 hours References [1].3GPP TS 25.122 V4.4.0, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Terminal Conformance Specification; Radio transmission and Reception (TDD) (Release 4), June, 2002 5-6 User Equipment Adjacent Channel Selectivity

Chapter 6: TD-SCDMA Signal Source Designs Introduction The TDSCDMA_SignalSource project demonstrates the special transient characteristics of TD-SCDMA signals from time and frequency domains, as well as rate matching calculation. Design examples in this project are described in the following sections: Uplink signal characteristics: TDSCDMA_UL_Spectrum.dsn. Downlink signal characteristics: TDSCDMA_DL_ACLR.dsn. Rate matching calculator demonstration: TDSCDMA_RM_Cal_Demo.dsn Introduction 6-1

TD-SCDMA Signal Source Designs Uplink Signal Characteristics TDSCDMA_UL_Spectrum.dsn Description This design demonstrates user equipment out-of-band emissions; these are unwanted emissions immediately outside the nominal channel that result from the modulation process and non-linearity in the transmitter but excluding spurious emissions. This out-of-band emission limit is specified in terms of a spectrum emission mask and adjacent channel power. The spectrum emission mask of the user equipment applies to carrier frequencies that are between 0.8 and 4.0 MHz. The out-of-channel emission is specified relative to the user equipment output power measured in a 1.28 MHz bandwidth. The power of any user equipment emission cannot exceed the levels specified in Table 6-1. Table 6-1. Spectrum Emission Mask Requirements f in MHz Minimum Requirements Measurement Bandwidth 0.8-35 dbc 30 khz 0.8-1.8 30 khz f 35 14 ------------- 0.8 MHz dbc 1.8-2.4 30 khz f 49 25 ------------- 1.8 MHz dbc 2.4-4.0-49 dbc 1 MHz Notes: f is the separation between the carrier frequency and the center of the measuring filter. The first and last measurement positions with a 30 khz filter at f equals 0.815 and 2.385 MHz. The first and last measurement positions with a 1 MHz filter at f equals 2.9 and 3.5 MHz. The lower limit must be -55dBm/1.28MHz or the minimum requirement presented in this table, whichever is higher. The top-level schematic for this design is shown in Figure 6-1. TDSCDMA_UL_RF generates a 12.2 kbps uplink RF signal source that includes one DPCH. 6-2 Uplink Signal Characteristics

The SpectrumMeasure subnetwork, Figure 6-2, measures the out-of-band emission spectrum and the average power measured in a 1.28 MHz bandwidth centered at the carrier frequency. Figure 6-1. TDSCDMA_UL_Spectrum Schematic Uplink Signal Characteristics 6-3

TD-SCDMA Signal Source Designs Simulation Results Figure 6-2. SpectrumMeasure Subnetwork Schematic Simulation results displayed in the TDSCDMA_UL_Spectrum.dds data display window are shown in Figure 6-3. 6-4 Uplink Signal Characteristics

Benchmark Figure 6-3. Simulation Results Hardware Platform: Pentium III 800 MHz, 512 MB memory Software Platform: Windows 2000, ADS 2002 Simulation Time: approximately 1 hour References [1] 3GPP Technical Specification TS 25.102 V4.2.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; UTRA(UE) TDD; Radio Transmission and Reception (Release 4) 2000-12. Uplink Signal Characteristics 6-5

TD-SCDMA Signal Source Designs Adjacent Channel Power Leakage Ratio TDSCDMA_DL_ACLR.dsn Features ACLR measurements for TD-SCDMA downlink 12.2 kbps downlink reference measurement channel Roll-off α = 0.22 root raised-cosine filter Description This example measures ACLR for TD-SCDMA downlink. The schematic for this design is shown in Figure 6-4. TDSCDMA_DL_RF generates the 12.2 kbps downlink reference channel for the measurement. The SpectrumMeasure subnetwork implements average power measurement through a root raised-cosine filter. By offsetting the center frequency of the root raised-cosine filter, power leakage on the adjacent channel is measured. Figure 6-4. TDSCDMA_DL_ACLR Schematic 6-6 Adjacent Channel Power Leakage Ratio

Simulation Results Simulation results displayed in the TDSCDMA_DL_ACLR.dds data display window are shown in Figure 6-5. Benchmark Figure 6-5. ACLR Measurements for TD-SCDMA Downlink Hardware Platform: Pentium II 400MHz, 523MB memory Software Platform: Windows NT Workstation 4.0, ADS 2002 Simulation Time: approximately 20 minutes References [1].3GPP TS 25.105, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; UTRA(BS) TDD; Radio transmission and Reception (Release 4), version 4.3.0, Dec., 2001. Adjacent Channel Power Leakage Ratio 6-7

TD-SCDMA Signal Source Designs Rate Match Calculator TDSCDMA_RM_Cal_Demo.dsn Description This design demonstrates the use of TDSCDMA_RM_Cal rate matching calculator model. The puncture limit and rate match attributes are specified by users when they configure TDSCDMA Design Library models related to rate matching. In TDSCDMA specifications, frame sizes before and after rate matching are supplied for reference measurement channels only. TDSCDMA_RM_Cal calculates the puncture limit and rate match attributes from the given frame sizes. The schematic for this design is shown in Figure 6-6. Simulation Results Figure 6-6. TDSCDMA_RM_Cal_Demo Schematic Simulation results displayed in TDSCDMA_RM_Cal_Demo.dds are shown in Figure 6-7. 6-8 Rate Match Calculator

Benchmark Figure 6-7. Puncture Limit and Rate Match for each Transport Channel Hardware Platform: Pentium IV 2.26 GHz, 512 MB memory Software Platform: Windows 2000, ADS 2003C Simulation Time: 4 seconds References [1] 3GPP Technical Specification TS 25.222 V4.4.0, Multiplexing and channel coding (TDD) Release 4. Rate Match Calculator 6-9

TD-SCDMA Signal Source Designs 6-10 Rate Match Calculator

Chapter 7: TD-SCDMA Transmitter Designs Introduction The TDSCDMA_Tx project demonstrates user equipment and base station characteristics. Design examples in this project are described in the following sections: Base station error vector magnitude: TDSCDMA_DL_EVM.dsn. User equipment code domain power: TDSCDMA_UL_CDP.dsn. Introduction 7-1

TD-SCDMA Transmitter Designs Base Station Error Vector Magnitude TDSCDMA_DL_EVM.dsn Description This design demonstrates the base station error vector magnitude measurement to determine the difference between the reference waveform and the measured waveform. This difference is called the error vector. Both waveforms pass through a matched root raised-cosine filter with a bandwidth corresponding to the considered chip rate and roll-off a =0.22. Both waveforms are then further modified by selecting the frequency, absolute phase, absolute amplitude and chip clock timing so as to minimize the error vector. The EVM result is defined as the square root of the ratio of the mean error vector power to the mean reference power expressed as a percentage. The measurement interval is one time slot. The error vector magnitude (EVM) cannot exceed 12.5%. The requirement is valid over the total power dynamic range as specified in subclause 6.4.3 of TS 25.105. The top-level schematic for this design is shown in Figure 7-1. TDSCDMA_DL_RF is used to generate a 12.2 kbps uplink RF signal. TDSCDMA_EVM is used to measure the EVM value of the RF signal. The algorithm is the same as that of VSA89600. Simulation Results Figure 7-1. TDSCDMA_DL_EVM.dsn schematic Simulation results are shown in Figure 7-2. 7-2 Base Station Error Vector Magnitude

Figure 7-2. TDSCDMA_DL_EVM.dsn Simulation Results Base Station Error Vector Magnitude 7-3

TD-SCDMA Transmitter Designs Benchmark Hardware Platform: Pentium II 400 MHz, 512 MB memory Software Platform: Windows NT 4.0, ADS 2003A Simulation Time: 1 minute References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. 7-4 Base Station Error Vector Magnitude

User Equipment Code Domain Power TDSCDMA_UL_CDP.dsn Description This design demonstrates the code domain power measurement of user equipment. Code domain power is the part of the mean power which correlates with a particular (OVSF) code channel. The sum of all powers in the code domain equals the mean power in a bandwidth of (1+ a) times the chip rate of the radio access mode. The top-level schematic for this design is shown in Figure 7-3. TDSCDMA_DL_RF is used to generate an uplink RF signal. VSA_89600_1_Sink is used to start the VSA89600 software to measure the RF signal. ESG_E4438C_Sink is used to send I, Q data to ESG. Simulation Results Figure 7-3. TDSCDMA_UL_Link.dsn Schematic Simulation results are displayed in a VSA89600 window are shown in Figure 7-4. User Equipment Code Domain Power 7-5

TD-SCDMA Transmitter Designs Benchmark Figure 7-4. TDSCDMA_UL_Link.dsn Simulation Results Hardware Platform: Pentium II 400 MHz, 512 MB memory Software Platform: Windows NT4.0, ADS 2002C, VSA89600 4.00x2_BETA Simulation Time: 1 minute References [1] 3GPP Technical Specification TS 25.142 V4.5.0 3rd Generation Partnership Project; Technical Specification Group Radio Access Networks; Base station Conformance (TDD) (Release 4) June, 2002. 7-6 User Equipment Code Domain Power

Index B BER performance, 2-1 BLER performance, 2-1 burst structure, 1-2 I instrument links, 3-1 J joint detection receiver, 1-3 P physical layer, 1-1 power amplifiers, 4-1 R Rake receiver, 1-3 receivers, 5-1 S signal sources, 6-1 smart antenna, 1-1 T TD-SCDMA standard, 1-1 time slots, 1-1 transmitter structure, 1-2 transmitters, 7-1 U uplink synchronization, 1-1 Index-1

Index-2